Graphic indicator responsive to a plurality of conditions in a continuous processing system



April 15, 1952 E. UTTERBACK ETAL GRAPHIC INDICATOR RESPONSIVE TO A PLURALITY OF CONDITIONS IN A CONTINUOUS PROCESSING SYSTEM Filed Sept. 7, 1944 &

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INVENTORS ROY E1 DOOL EV April 15, 1952 GRAPHIC INDICATOR RESPONSIVE TO A PLURALITY OF CONDITIONS IN A CONTINUOUS PROCESSING SYSTEM Filed Sept. 7, 1944 OUT E. UTTERBACK H AL 8 Sheets-Sheet 2 OUT INVENTORS BY ROY {5.0000457 Q ATTO R N EY April 15, 1952 UTTERBACK E 2,593,224

GRAPHIC INDICATOR RESPONSIVE TO A PLURALITY OF CONDITIONS IN A CONTINUOUS PROCESSING SYSTEM Filed Sept. 7, 1944 8 Sheets-Sheet 3 J/ I) J2 g2 J2 J4 400 500 600 700 800 .900 I000 I100 I200 1300 "F DAMPER POSITION 3 mam AIR //V INVENTORS Aprll 15, 1952 E UTTERBACK ETAL 2,593,224

GRAPHIC INDICATOR RESPONSIVE TO A PLURALITY OF I CONDITIONS IN A CONTINUOUS PROCESSING SYSTEM Filed Sept. 7, 1944 8 Sheets-Sheet 5 ATTORNEY P" 15, 1952 E. UTTERBACK ET AL 2,593,224 GRAPHIC INDICATOR RESPONSIVE TO A PLURALITY OF CONDITIONS IN A CONTINUOUS PROCESSING SYSTEM Filed Sept. 7, 1944 s SheetsSheet e A5? my m we #5 I PTWTWTWW I #0 12/ 9- a 75 0mg? Relays J7 INVENTOR 5 ERNEST u TI'ZRBHC/f lV/ll/AM A. HAGERBA UMER ROYE.DO0LEY BYXW 6W ATT ORNEY April 15, 1952 E. UTTERBACK ET AL 2,593,224

GRAPHIC INDICATOR RESPONSIVE TO A PLURALITY OF CONDITIONS IN A CONTINUOUS PROCESSING SYSTEM Filed Sept. 7, 1944 8 Sheets-Sheet 7 m" 4 Slade M/e aperazed 754 5y fieeoraer 1 d Swz'lcb operated by Recorder 0 v A.C..

INVENTORS ERA/57 UTTERBflC/f WILL/AM A.H 4GER5HUMER ROY E. OOOLEY April 15, 1952 Filed Sept. 7, 1944 E. UTTERBACK EI'AL GRAPHIC INDICATOR RESPONSIVE TO A PLURALITY 0F CONDITIONS IN A CONTINUOUS PROCESSING SYSTEM 8 Sheets-Sheet 8 7E3 016- Relays W/LL/HM ROY 5.00045? BY a g g X kAQTORNEY Patented Apr. 15, 1952 GRAPHIC INDICATOR RESPONSIVE TO A PLURALITY OF CONDITIONS IN A CON- TINUOUS PROCESSING SYSTEM Ernest Utterback, Upper Darby, William A.

Hagerbaumer, Brookline, Pa.,

and Roy E.

Dooley, Rockaway, N. J., assignors to Socony- Vacuum Oil Company, Incorporated, New York, N. Y., a corporation of New York Application September 7, 1944, Serial No. 553,054

2 Claims. 1

This invention relates generally to graphic indicating devices and more particularly to indicating devices for keeping the operator of continuous processing equipment; informed of the conditions of the equipment.

In the operation of modern continuous processin equipment, the success of the entire process depends upon continually keeping operations in step withv respect to various variables, such as, temperature, velocity or time; for example, any slow down of one end of a unit timing would seriously upset the operation of other parts of the unit.

This condition has been encountered in the prior art and met on commercial units by the installation of a multiplicity of recording instruments and indicators to permit the operating crew to keep informed of the conditions of the unit. Because of the speed with which changes occur in large installations, it is necessary to have some form of analyzing or indicating equipment by means of which an operator can size up the situation at a single glance. It is the purpose of this invention to provide such equipment.

As an example, the operation of an indicator of this type as applied to a process for catalytic conversion of hydrocarbons will be described. Recentiy such a process has taken the form of a system wherein a particle form solid catalytic material is cyclically passed through a conversion zone wherein it is contacted with hydrocarbon vapors and a regeneration zone wherein it is contacted with a combustion supporting gas acting to burn off a contaminant deposited on the catalyst in the conversion zone. A commercially successful process of this type is the Thermofor" catalytic cracking process.

In the operation of a "Thermofor catalytic cracking unit, it is essential that the temperature vertically throughout the reactor and temperatures vertically and horizontally throughout the burners or regenerators be maintained at certain predetermined levels. With a multiplicity of burners or regenerators it is essential that the temperature group in each burner be related. It is desirable at the same time to readjust temperature levels if the volume of charge passing through the unit is to increase, or if certain other conditions are to be met.

The temperature conditions throughout the reactor and regenerator are usually measured by means of thermocouples advantageously placed at different vertical levels throughout the height of the reactor or regenerator. These thermocouples are connected to separate recording and indicating circuits. It is not unusual to use as many as twenty separate thermocouples in a single reactor or regenerator which necessitates a like number of individual indicators for indicating the temperature registered by each thermocouple. During the operation of a Thermofor" catalytic cracking unit it is necessary that the zone adjacent each thermocouple be kept within a narrow range. Each zone may have a different temperature range, therefore, no two of the plurality of indicating devices, in the example used, twenty, when operating under the proper conditions, would necessarily read the same. Therefore, it is readily apparent that it is no small task for the operator of the unit to try to watch all of these indicators and at the same time make necessary adjustments to the unit to maintain the necessary conditions in all zones of the reactor or regenerator.

The present invention solves the problem for the operator by providing a graphic indicator which will give in a single diagram, an indication of the conditions existing in all of the zones in the reactor or regenerator and at the same time, if desired, compare these conditions to a characteristic curve that represents optimum operating conditions.

This is accomplished by providing a panel with a plurality of vertically spaced, horizontally movable indicators which move with reference to adjacent temperature scales carried by the panel. The indicators are selectively operated through an electrical system that is controlled by a rheostat or a slide wire mounted on the same shaft with the slide wire in the multipoint potentiometer temperature recorder which this invention supplements.

Therefore, the primary object of this invention is to provide a graphic indicator that will show on a single chart or diagram the conditions existing in all of the zones of a reactor or regenerator.

Another object of this invention is to provide a graphic indicator that will accurately and simultaneously show a plurality of related temperatures.

Still another object of this invention is the provision of a graphic indicator that will give a temperature profile of a regenerator or reactor and means for operating same.

This invention further contemplates electrical means for selectively operating a plurality of indicators to effect a graphic indication of the conditions existing in a continuous processing system.

It is a further object of this invention to pro- 'vide a graphic indicator that can be operated through an electrical system by a conventional multipoint potentiometer recorder.

Another object is the provision of a graphic indicator that is fully automatic in its operation.

Other objects and advantages will become apparent from the following detailed description when considered with the drawings, in which Figure 1 is a diagrammatic illustration of a Thermofor catalytic cracking operation;

Figure 2 is a vertical section of a regenerator or burner unit showing the location of controlled temperature zones;

Figure 3 is a characteristic curve illustrating operating conditions in a Thermofor catalytic cracking regenerator which has been plotted with temperature as abscissa and position of thermo couples as ordinates;

Figure 4 is a vertical elevation of the graphic indicator as contemplated by the present inventionj Figure 5 is a diagrammatic illustration of one form of electrical control system for the graphic indicator;

Figure dis a simplified wiring diagram showing the electrical system as applied to one pointer; V

Figure 7 is a diagrammatic illustration of a modified form of electrical control system for the graphic indicator;

Figure 8 is a simplified wiring diagram showing the system disclosed in Figure 7 as applied to a single pointer; and

Figure 9 is a still further modified form of electrical control system for the graphic indicator.

Referring to the drawings in detail, particularly Figure 1, there is shown diagrammatically a Thermofor catalytic cracking unit adapted for continuous operation comprising a reactor l9 and a regenerator or burner ll. Hydrocarbon gases to be cracked are fed into the reactor through an inlet pipe l2. These gases are introduced in countercurrent to the flow of catalyst, usually in pellet form, that is admitted through the inlet pipe l3. The cracked gases are drawn off by way of outlet I4 and are selectively passed on to other stages of the process not shown. The catalyst with pellets coated with coke passes out of the reactor at the bottom through an outlet pipe 15, through which it is fed to an elevator l6. Elevator It carries the catalyst up to an elevator discharge I! through which it is fed by gravity directly into the regenerator or burner II. The catalyst passes downwardly through the regenerator traversing a plurality of zones having controlled temperature where air is fed into the re generator to burn off the coke deposited on the catalyst while passing through the reactor. Each zone traversed by the catalyst therefore has controlled heating and/or controlled cooling. The regenerated catalyst leaves the regenerator through the outlet I8 through which it is caused to flow into a second elevator [9 which raises the catalyst and dumps it through the elevator outlet 211 into a hopper 2!. The hopper 2| feeds the catalyst back into the reactor at a controlled rate where it is again used for cracking the hydrocarbon gases. Since this cycle is continuous the need for a multiplicity of controls i apparent, and wherever a control is needed an indicator of the condition to be controlled must be used.

As an example of the many controls needed,

having a plurality of burning zones, such as shown at 22, into which air is fed by means of tuyeres 23 that are connected to supply pipes 24, for the purpose of burning the coke from the catalyst. The catalyst, having the coke deposited thereon, is fed into the regenerator by means of pipe ii at a controlled rate at a temperature falling within the range of 700-1200 F. The catalyst, by gravitational force, passes through the successive zones and out through the outlet 58. As the catalyst traverses each zone, the air admitted by the tuyeres 23 causes a portion of the deposit carried by the catalyst to be burned off, thereby raising the temperature of the catalyst. The products of combustion escape through the outlets 25. If the temperature exceeds a certain critical temperature the catalyst will be ruined. Therefore, thermocouples 25 are inserted in each burning zone by means of which the temperature can be watched and controlled accordingly. There are interposed between the burning zones 22, cooli'ng zones 21. Coolant is supplied to these zones by means of pipe coils 28 that are con nected through uitable control valves to supply lines 29. As the catalyst with temperature raised passes each of the burning zones 22 it enters one of the cooling zones 21 where its temperature is brought down to a predetermined level. Thermocouples 3%] are inserted in these cooling zones so that the amount of cooling in each zone can be watched and controlled. The catalyst, therefore, in traversing the regenerator I I, successively passes through alternate burning and cooling zones. It is not unusual to have as many as ten burning zones and as many cooling zones in a regener'ator, each one having at least one thermocouple and associated indicator. No two of the indicatcrs would necessarily read the same temperature, but they would bear an overall relationship. In addition to the twenty thermocouples required for the heating and cooling zones one is needed in the inlet to indicate the temperature of the catalyst as it enters the regenerator and one is needed in the outlet to indicate the temperature of the catalyst as it leaves. For the regenerator alone, by prior art methods, twentytwo separate indicators would be needed. As pointed out above it is no small job for an operator to watch twenty-two disassociated indicators and make the necessary adjustments at the same time to maintain the desired operating conditions in the regenerator. It is to a problem of this character that this invention has direct application.

The nearest approach to a solution of this problem has been the use of multipoint recorders which record on a single recorder strip a plurality of temperatures. Although the multipoint temperature recorder is a very efiicient instrument for making a permanent record of temperatures sensed by the various thermocouples it does not provide the operator with a continuous graphic indicator that will show at a glance a temperature profile of the regenerator.

If the desired thermocouple temperatures are plotted as abscissa against the position of the thermocouples as ordinates, a characteristic curve representing the desired operating conditions will be obtained. Such a curve is illustrated in Figure 3. A curve of this character, in a manher to be describedlater, can be placed on a graphic indicator panel and will serve as a reference curve for another which represents instantaneou operating conditions, that can be plotted electrically on the same panel.

The graphic indicator as contemplated by the present invention is illustrated in Figure 4. Here it is shown as an indicator of temperatures in the different zones of a regenerator in a Thermofor catalytic cracking system. The panel 3I is provided at its left side with a diagrammatic illustration of a vertical section of the regenerator showing the burning and cooling zones and the positions of the thermocouples which sense the temperatures that are to be indicated. The right side of the panel is provided with a system of coordinates comprising the vertical lines 32 and the transverse slots 33. The horizontal axis of the system represents degrees Fahrenheit (400-1300) and the vertical axis represents the position of the thermocouple.

The slots 33 are respectively provided with indicators or pointers 34 that are adapted to move in their respective slots to indicate the temperatures measured by the thermocouples 26. These pointers, when connected over the face of thepanel by elastic lines 35 will describe a curve which indicates the instantaneous operating conditions of the regenerator. As pointed out above, this curve can be readily compared to one which represents optimum operating conditions that has been drawn on the board. The optimum operating conditions curve can be painted on the panel if the operating conditions are not to be changed, but if a change of operating conditions. is contemplated the curve can be placed on the panel by chalk so that it can be erased.

In Figure there is illustrated the preferred embodiment of the electrical system for operating the pointers on the graphic temperature indicator.

Control and operation of the system is effected through a multipoint temperature recorder 31. The recorder is conventional and is of the type now in common use for recording the thermocouple temperatures.

The conventional recorder, diagrammatically illustrated at 31 is already equipped with thermocouple selector switch 38 which is mounted for operation on a shaft 39. For the present invention an additional selector switch 49 is mounted on shaft 39 and is synchronized with switch 33 for selectively preparing electrical circuits for the operation of the pointers 34 by completing power supply circuits through the coils 4| of relays 42. Power is supplied to the windings 4i of the relays 42 from a 110-115 volt A. C. source through conductors 43, 44, 45 and 46, selector switch 40, conductors 41, 4B and 49. Energization of one of the relays 42 will cause its armature, which carries four contactors, to close circuits for means which actuate one of the pointers 34.

In addition to the selector switch 40 a commutator 50 is mounted on shaft 39 for rotation therewith. Its function will be described in connection with the pointer operating circuits.

The conventional multipoint potentiometer recorder is equipped with a second shaft 5| that is driven by the recorder motor to drive a slide wire 52. For purpose of the present invention a second slide wire 53 is mounted on the outer end of shaft 5| for rotation therewith.

The system illustrated in Figure 5 is for the selective operation of all of the pointers 34. In order to more readily understand the operation of this system, reference will first be made to Figurefi, which illustrates the manner in which a single pointer is operated.

Referring now to Figure 6, voltage divider 54 corresponds to the slide wire 53 of Figure 5. The

resistance element of the voltage divider 54 is connected in parallel with the resistance element of a second voltage divider 55a which corresponds to the potentiometer 55 of Figure 5. D. C. voltage is supplied to this parallel combination from a 110 volt, A. C. source, not shown, through the conductors 58, transformer 51, rectifier 58, resistance 59, conductors 60, BI and 62. Condenser 63 is provided to reduce the ripple of the rectified voltage. Resistance 59 is provided to lower the voltage applied to the voltage dividers or poten-. tiometers 54 and 55a.

Contactors 64 and 65 of the potentiometers 54 and 55a are respectively connected to the grids 66 and 67 of the tetrode sections 68 and 99 of two type ll'I-L-7 tubes. The diode sections of these tubes are the rectifiers 58 and 19. The position of the contactors 64 and 95 determines the negative bias potential applied to the tetrodes 68 and 69. The resistance values of potentiometers 54 and 55a and resistor 59 are chosen so that this bias will have a range from zero to cutoff for the tetrodes 68 and 69. Resistance H is provided to by-pass a portion of the current flowing through the resistance elements of the potentiometers 54 and 55a so that a wider range of adjustment can be provided for the bias potential placed on the grids 66 and 61 of tubes 68 and 69, respectively.

Tube 69 and resistance I2 form one-half of a Wheatstone bridge while tube 69 and resistance l3 form the other half. The plate of tube 69 is supplied with a D. C. potential from transformer 51, diode 53, conductors l4 and 15, commutator 59, resistance 13, conductors TI, 18, I9 and E9, resistance ii and the conductor 80.. The plate of tube 98 is supplied with D. C. potential from transformer 51, through diode 58, conductors I4 and I5, commutator 50, resistance '12, conductors 8!, 82, I9 and 60, resistance II and conductor 89. The screens of tubes 68 and 69 are connected together with the conductors 83 and 84 and are supplied with potential from the plate circuits of the tubes by conductor 85. Condenser 85 forms a by-pass to the cathodes of tubes 59 and 59 for the. plate and screen grid circuits.

The signals developed in the plate circuit of these two tubes when impressed across the resistors l2 and 73, cause a current to flow through the resistances 81 and 88 and the resistance element of the potentiometer 89. This potential is applied to the grids 99 and 9| of the gas triodes 92 and 93, respectively through the resistances 94 and 95. The functions of the resistances 94 and are to limit the grid current in the gas triodes on the negative swings of the alternating plate voltage. The potentiometer 89 provides a means for compensating for the difference in characteristics of the gas triodes 92 and 93. The filaments of tubes 92 and 93 are supplied with A. C. power through the transformer 95 whose primary is connected to the volt, 6O cycle source through conductors 97 and 98. A common D. C. grid bias potential for tubes 92 and 93 is provided by rectifier I9, through resistors 99 and I95 and condenser Ifil. The bias circuit is completed by the conductor I02, which is connected to the power supply conductor 98. The plate circuit of gas triode 92 includes conductor I33, one winding of the reversible motor I94, conductor I95, the 110 volt, 60 cycle power supply and conductors 98, I92 and H19. The plate circuit of gas triode 93 includes conductors I99, the other winding of the reversible motor conductive.

nu, een'aueter js'ct, "the yea, so cycle ewer supply-and conductors 98, I32 and I I0.

As shown diagrammatically in Figure '6 the reversible motor I34, through the pulley I II and the belt H2, formed ofpiano wire or wire such as that used in violin strings, drives the contactor 55, carried by the belt, on the resistance element of potentiometer 55a. Also-secured to belt H2 is the pointer 34 which cooperates with the stationary scale H3 that is calibrated in temperature units.

In the operation of the circuit of Figure 6, a change of the adjustment of potentiometer 54, by the rotation of'shaft 55 in the multipoint potentiometer recorder 3?, will cause a proportional change in the current passed by tube 53. This unbalances the bridge and a potential appears across resistances '8? and 83 and potentiometer 89. This potential appears as the resuit of the difference in potential developed across the resistances l2 and E3. The direction of the potential appearing across the resistances 87 and 38 and the potentiometer 89 determines which of gas triodes of tubes 92 and 93 will become When one of these tubes becomes conductive, power is passed to motor I54 which turns in the direction necessary to move contactor 55 of potentiometer 55a and changes the bias on tube 65. This balances the bridge, and and the potential across resistors 8? and t3 and potentiometer 83 disappears and allows the gas triode to again become non-conductive on the next cycle of the alternating plate potential.

Commutator 5c is connected in the plate circult of tubes 68 and 63 so that the plate potential can be taken off these tubes while the circuit through the relays M is broken by the selector switch changing from one contact to the next. This prevents a surge of current in the plate circuit of these tubes due to the momentary removal of the bias therefrom when connection is changed from one of the voltage dividers 55a to the next which is associated with the next pointer to be actuated.

Now again, referring to Figure 5, it will be seen that rotation of shaft 39 to cause selector switch 38 to select a thermocouple whose temperature is to be recorded by the recorder 31 causes selector switch 49 to complete a circuit to the power supply for one of the relays 4I.

Energization of one of the relays 4| in addition to completing motor circuits completes circuits through one of the voltage dividers 55 to operate the pointer 34 associated therewith. After selection of the thermocouple, whose temperature is to be indicated, and the pointer, that is to indicate that particular temperature, shaft 5! of the recorder 37 turns to record the temperature, thereby causing a rotation of the slide wire 53 which corresponds to the voltage divider 54 of Figure 6, to change its adjustment. This, as described in connection with Figure 6, unbalances the bridge which comprises the tubes 63 and 53 and resistances "I2 and '53. These two tubes are connected in such a manner that the voltages developed across resistances I2 and it will be subtracted and the resultant potential will be applied across resistances 8i and 88 and po tentiometer 89.

Depending upon the direction of the current through resistances 8'1, and 88 and potentiometer 89, one of the gas triodes 92 or 33 will fire and current will flow through one winding of the reversible motor I64. Motor I84 will thendrive the contactor 65 of the slide wire or voltage 8 divider 55 to aposition such that thejblld win again be balanced. When the bridge is balanced tube 92 or 93 that fired will cease firing and motor I34 will stop. The pointer 34 bein'g'secured to the belt I'I2, whose drive is synchronized with that of contactor 55 will indicate this new temperature on the scale carried by the panel. 7

A modification of the operating, mechanism for the pointers 34 is diagrammatically shown in Figure 7. In the same mannerjasjdescribed in connection with Figures 5 andfi, an additional selector switch '40 for selecting the pointer to be operated is added to that ofthe conventional recorder 31. Additionally, a second slidewire 53 is mounted on 'the s'ame shaft with,, 'he one that is already in the conventional "'dfer. Selector switch 40 completes powerlcircu tsffor the solenoid'operated relays II5. Power 'i'ssupf. pliedfrom a volt, alternating current source through conductors H6, H1 and H8, selector switch 40, conductors H9, I28 and I2I. Ene'rgization of one of the solenoid operated relays II5 causes its armature to close three 'contactors I22, I23 and I24. Contactor I22 and I23 complete circuits through the windings or a reversible motor I25 which, through shaft I26, drives, the pulley I27 and slide wire I28. Pulley I21 drives a belt I29 which passes around a second pulley i235 mounted on a shaft I3'I. Belt I23, a's derscribed above, may be formed of piano wire or similar material. Belt I29 carries a pointer 34 which cooperates with a stationary scale to indi cate temperature. In this form of the invention, although each pointer 34 is provided with aseparate reversible motor I25 and slide wire I28, a common meansflis used for selectively supplying power to them through the relays I I5.

In Figure 8 the circuit for supplying power to a single motor is shown in detail. ,1 In this diagram, rheostat I32 corresponds to the slide wire 53 in the recorder of Figure 7 and rheostat I33 corresponds to one of the slide wires I28,0f Figure 7. Rheostat I32 with rheosta't I33 and the primary windings I34 and I 35 of transformers I35 and :31, respectively, term aWheatstone bridge circuit. The Wheatstone bridge circuit is supplied with power from a 110 volt A. C. source, not shown, through conductors I38 and I39. The secondary windings I44 and MI of transformers I36 and I31 are connected in series and across the resistances I42 and I43. Resistors I42 and I43 are connected respectively in the gridcir} cuits of gas triods I44 and I45. Resistances I46 and 141 are provided to limit the grid current during the negative voltage swings of the alterhating plate potential supplied to these tubes A common direct current bias potential for tubes I44 and I45 is provided by impressing a direct current potential on the R. C. circuit comprising resistors I48 and I43 and the capacitor [50 through the diode rectifier tube I 5I Transformer I52 serves tosupply theproper potential for the filament orheater of the diode rectifier 15!. The filaments of gas triodes I44 and l45 are supplied" with power through transformer I53 whose primaryis connected through. con ductors I54 to the 110 volt alternating current source. The plate circuit of gas triode I44 includes the conductor I55, one winding of the reversible motor I25, conductor I5], the 110 volt A. C. power supply and conductors I58 and I59, The plate circuit of gas triode I45 includes the conductor I56, the second winding of rever ibie' mbtor. wndi i i i1 1 ihei fie ql terna in current power supply and conductors I58 arid I59.

The operation of the circuit shown in Figure 8 to actuate one of the pointers 34 is as follows: When the bridge is in balance the current from the 110 volt A. C. source divides itself equally between two halves of the bridge, one-half being made up of rheostat I33 and the primary winding I34 of transformer I33 and the other half comprising the rheostat I32 and the primarywinding I of transformer I31. The induced potential in the secondary winding I of transformer I33 is equal to and 180 out of phase with the induced potential in the secondary winding I M of transformer I31. Under these conditions no potential will exist across the two resistors I42 and I43. The negative grid bias potential for gas triodes I44 and I is sufficient that the tubes will not become conductive when the bridge is balanced. When the recorder 31 varies rheostat I32 in a direction that will decrease the resistance of rheostat I32 the bridge becomes unbalanced and more current will flow in that half than in the other half, resulting in an increased potential in the secondary winding I M of transformer I31. This secondary potential being greater than the potential in the secondary winding I40 and 180 out of phase with it produces a potential across resistors I42 and I43 equal to the difference of the potentials in the secondary windings I40 and MI and in phase with the potential of secondary winding I4I. This potential across resistors I42 and I43 will add to the negative bias on the grid of tube I45 and will subtract from the negative bias from the grid of tube I44. This causes tube I44 to become conductive and power is supplied to motor I25 which rotates in the direction to drive contactor I of rheostat I33 toward a new bridge balance point. Since the belt IBI which drives contactor I also carries the pointer 34 it will be carried to a new position on the scale I32. When contactor I60 has been moved to the new balance point, the current is again equally divided in the two halves of the bridge and tube I44 becomes non-conductive because there is no potential across resistors I42 and I43 and the negative bias on its grid is again sufiicient to keep it from being conductive.

When the recorder varies rheostat I32 in a direction that will increase the resistance of rheostat I32, the bridge becomes unbalanced and less current will i'iow in that half than. in the other half resulting in a decreased potential in the secondary winding I4I. This potential being less than potential in the secondary winding I40 and 180 out of phase with it. there will be produced across resistors I42 and I43 a potential that is equal to the difierence of the potentials in the secondary windings I40 and i4! and in phase with the potential of secondary winding I43. This potential across resistors I42 and I43 will add to the negative bias on the grid of tube I44 and will subtract from the negative bias on the grid of tube I45. This causes tube I45 to become conductive and power is supplied to motor I25 which rotates in the direction to drive contactor I30 toward a new balanced position. When contactor I 33 has been moved to the new balanced point the current is again equally divided in the two halves of the bridge and the tube I44 becomes non-conductive because there is no potential across resistors I42 and I43 and the negative bias on its grid is again sufficient to keep it from being conductive.

Again referring to Figure '7 it will be seen that the circuits of Figure 8 are used to actuate the separate pointer drives selectively through the re-. lays II5.

In Figure 9 there is shown still another modification of the present invention. This differs from the embodiment shown in Figures 7 and 8 in that a single motor selectively drives the pointers 34 and the contactors I60 therough solenoid operated clutches.

In this form of the invention selector switch 40, which is synchronized with the recorder thermocouple selector switch 38, completes an ener-' gizing circuit through one of the solenoid operated relays 203. The armature of that relay 'closes a pair of contacts 20I, and 202 carried thereby to set up indicator operating circuits. Assuming for purpose of explanation that the top relay has been actuated then power is supplied to the winding of the top solenoid operated clutch 233 to draw a gear 204 that is splined or keyed to the shaft 205 of motor 203, up into engagement with a second gear 201. Gear 201, through shaft 208, drives a pulley 209 and belt 2I0 to move the contactor I50 and pointer 34.

Energization of the top relay also connects rheostat I33 in a bridge circuit with the primary windings of transformers I33 and I3! and the slide Wire 53 operated by the recorder 31. Rheoseat I33 with winding I34 forms one-half of the bridge circuit and slide wire 53 and winding I35 forms the other half of the bridge circuit. A. C. power is supplied to the bridge by conductors 1 I6, 2| I and 2I2 to the juncture of the primary windings I34 and I35, and conductors II! and 2I3 to the juncture of conductors leading to the rheostats 53 and I33. Unbalancing the bridge by an alteration of the setting of rheostat 53 has the same eiiect as that explained in connection with Figures 7 and 8.

Although the present invention has been dedescribed in detail in connection with units for the catalytic conversion of hydrocarbons, it is to be understood that it has application wherever multipoint recorders can be used. Additionally, only three modifications have been shown and described, but it is to be understood that the invention is only to be limited by the appended claims.

We claim:

1. A graphic indicator for continuously indicating a plurality of varying conditions in a continuously operating system that comprises a panel having a system of rectangular coordinates thereon; a plurality of pointers corresponding in number to the number of conditions to be indicated spaced along one axis of said coordinates, adapted to be moved over the other axis of said coordinates; reversible motor means for each of said pointers for actuating the same when said reversible motor means is energized; energizing means selectively responsive to said conditions for energizing said reversible motor means in the direction of and in proportion to the magnitude of the variation in one of said conditions being indicated; a pointer selector for selectively establishing energizing relation between said energizing means and said reversible motor means, said pointer selector being adapted to establish said energizing relation synchronously with respect to the selective response of said energizing means to the variation in said conditions.

2. A graphic indicator for continuously indicating a plurality of varying conditions in a continuously operating system that is adapted for use in combination with a multipoint potentiometer recorder that comprises in combination a: panel having a; system of: rectangular coordi,

nates thereon; a plurality of pointers, corresponding innumber to; the-number of conditions t0-be=recorded-and tobe indicated spaced along one axis of-- said coordinates and adapted to-be moved over the-other: axis of saidcoordinates; pointerselector means actuated bysaid recorder and synchronized therewith with respect to conditions: recorded thereby and adapted to completeelectrical circuits associated with the oper ationof each of said pointers; an impedance bridge circuit; means-for supplying power to said bridge circuit; means also actuated by said recorder-for varying'the impedance of one element ofthebridge circuit to unbalance thebridge; meansoperable: by the unbalanced bridge current through. said circuits" completed by said pointer selectormeans for actuating the pointer associated with said circuit an amount-proportionalto the change in the'condition: to be indi-.

cated; additional means-actuated:bynsaid pointer actuating means fonvarying -asecond? impedance:

elementinr said bridge circuit to bring the bridge back'intolbalancedacondition.

ERNEST UTTERBACK; WILLIAM A. HAGERBAUMER. ROYfE. DOOLEY;

REFERENCESj-v CITED The follpwi-ngreferences are of record in me file. of 1 thispatent:

UNITED STATES; PATENTS 

